Integrated circuit and anti-interference method thereof

ABSTRACT

An integrated circuit for driving a display panel and an anti-interference method are provided. The integrated circuit can include a source driving circuit and an anti-interference circuit. The source driving circuit includes a receiving circuit configured to receive an input signal including image data and process the input signal based on at least one operation parameter to generate output data. The anti-interference circuit is coupled to the receiving circuit. The anti-interference circuit can determine whether an interference event occurs to the input signal based on the input signal or the output data to obtain a determination result and determines whether to adjust the at least one operation parameter of the receiving circuit according to the determination result.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of and claims thepriority benefit of a prior application Ser. No. 16/231,418, filed onDec. 22, 2018, now pending. The prior application Ser. No. 16/231,418claims the priority benefits of U.S. provisional application Ser. No.62/666,662, filed on May 3, 2018. The entirety of the above-mentionedpatent application is hereby incorporated by reference herein and made apart of this specification.

BACKGROUND Field of the Invention

The invention relates to an electronic circuit and more particularly, toan integrated circuit and an anti-interference method thereof.

Description of Related Art

When a mobile phone (or another radio frequency (RF) device) approachesa display apparatus, RF noise may cause abnormality to a display screenof the display apparatus. One of the reasons causing the abnormality isthat the RF noise of the mobile phone may interfere with transmission ofdata signal between a timing controller and a source driving circuit.

FIG. 1 is a schematic diagram of a scenario where a mobile phone 110approaches a display apparatus 120. A timing controller 121 transmits adata signal to a source driving circuit 122 through a transmission line,and the source driving circuit 122 drives a display panel 123 accordingto the data signal to display an image. When the mobile phone 110approaches the display apparatus 120, a RF noise 111 of the mobile phone110 may interfere with the transmission of the data signal between thetiming controller 121 and the source driving circuit 122. When theenergy of the RF noise in the data signal is sufficiently large, thesource driving circuit 122 may be incapable of correctly latching thedata signal.

FIG. 2 is a schematic diagram of a scenario where a signal received bythe source driving circuit 122 depicted in FIG. 1 is interfered by theRF noise. In FIG. 2, the horizontal axis represents the time, Rxrepresents the data signal received by the source driving circuit 122,and CDR_CLK represents a clock signal received by a clock and datarecovery (CDR) circuit disposed inside the source driving circuits 122.As illustrated in the left part of FIG. 2, when the RF noise 111 doesnot occur yet, i.e., no interference event occurs yet, the CDR circuitdisposed inside the source driving circuit 122 may correctly lock thedata signal Rx, i.e., a phase of the data signal Rx meets a phase of theclock signal CDR_CLK. When the RF noise 111 occurs, i.e., aninterference event occurs, the RF noise 111 may interfere with the datasignal Rx, such that the phase of the data signal Rx may not meet thephase of the clock signal CDR_CLK. Namely, the CDR circuit disposedinside the source driving circuit 122 may trigger loss of lock to thedata signal Rx. When the source driving circuit 122 is incapable ofcorrectly locking the data signal Rx, the display panel of the displayapparatus 120 certainly is incapable of displaying a correct image.

SUMMARY

The invention provides an integrated circuit and an anti-interferencemethod for self-determining whether an interference event occurs to aninput signal from the external, so as to determine whether to adjust atleast one operation parameter of a receiving circuit according to thedetermination result.

According to an embodiment of the invention, an integrated circuitconfigured to drive a display panel is provided. The integrated circuitincludes a source driving circuit and an anti-interference circuit. Thesource driving circuit includes a receiving circuit, and configured toreceive an input signal including image data and process the inputsignal based on at least one operation parameter to generate outputdata. The anti-interference circuit is coupled to the receiving circuit.The anti-interference circuit determines whether an interference eventoccurs to the input signal based on the input signal or the output datato obtain a determination result and determines whether to adjust the atleast one operation parameter of the receiving circuit according to thedetermination result.

According to an embodiment of the invention, an anti-interference methodof an integrated circuit is provided. The integrated circuit isconfigured to drive a display panel. The anti-interference methodincludes: receiving an input signal including image data by a receivingcircuit of a source driving circuit in an integrated circuit; processingthe input signal based on at least one operation parameter by thereceiving circuit to generate output data; determining whether aninterference event occurs to the input signal based on the input signalor the output data by an anti-interference circuit to obtain adetermination result; and determining whether to adjust the at least oneoperation parameter of the receiving circuit according to thedetermination result by the anti-interference circuit.

To sum up, the receiving circuit of the integrated circuit provided bythe embodiments of the invention can process the input signal from theexternal based on the at least one operation parameter, so as togenerate the output data to other internal circuits. Theanti-interference circuit of the integrated circuit can determinewhether any interference event occurs to the input signal, so as todetermine whether to adjust the at least one operation parameter of thereceiving circuit according to the determination result.

To make the above features and advantages of the invention morecomprehensible, embodiments accompanied with drawings are described indetail below.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are included to provide a furtherunderstanding of the invention, and are incorporated in and constitute apart of this specification. The drawings illustrate embodiments of theinvention and, together with the description, serve to explain theprinciples of the invention.

FIG. 1 is a schematic diagram of a scenario where a mobile phoneapproaches a display apparatus.

FIG. 2 is a schematic diagram of a scenario where a signal received bythe source driving circuit depicted in FIG. 1 is interfered by the radiofrequency (RF) noise.

FIG. 3 is a schematic circuit block diagram of a display apparatusaccording to an embodiment of the invention.

FIG. 4 is a schematic circuit block diagram of an integrated circuitaccording to an embodiment of the invention.

FIG. 5 is a flowchart of an anti-interference method of an integratedcircuit according to an embodiment of the invention.

FIG. 6 is a schematic circuit block diagram of the anti-interferencecircuit depicted in FIG. 4 according to an embodiment of the invention.

FIG. 7 is a schematic circuit block diagram of the common-mode leveldetection circuit in the interference detector circuit according to anembodiment of the invention.

FIG. 8 is a schematic circuit block diagram of the common-mode leveldetection circuit in the interference detector circuit according toanother embodiment of the invention.

FIG. 9 is a schematic circuit block diagram of the swing detectioncircuit in the interference detector circuit according to an embodimentof the invention.

FIG. 10 is a schematic circuit block diagram of the high frequencydetection circuit in the interference detector circuit according to anembodiment of the invention.

FIG. 11 is a schematic circuit block diagram of the error detectioncircuit in the interference detector circuit according to an embodimentof the invention.

FIG. 12 is a schematic circuit block diagram of the clock and datarecovery (CDR) circuit depicted in FIG. 4 according to an embodiment ofthe invention.

DESCRIPTION OF EMBODIMENTS

The term “couple (or connect)” herein (including the claims) are usedbroadly and encompass direct and indirect connection or coupling means.For example, if the disclosure describes a first apparatus being coupled(or connected) to a second apparatus, then it should be interpreted thatthe first apparatus can be directly connected to the second apparatus,or the first apparatus can be indirectly connected to the secondapparatus through other devices or by a certain coupling means.Moreover, elements/components/steps with same reference numeralsrepresent same or similar parts in the drawings and embodiments.Elements/components/notations with the same reference numerals indifferent embodiments may be referenced to the related description.

FIG. 3 is a schematic circuit block diagram illustrating a displayapparatus 300 according to an embodiment of the invention. The displayapparatus 300 includes a plurality of integrated circuits, for example,a timing controller 310 and one or more source drivers, as illustratedin FIG. 3. In FIG. 3, four source drivers 321, 322, 323 and 324 areillustrated; however, in any way, the number of the source drivers maybe determined based on a design requirement. The display apparatus 300further includes a display panel 330. The timing controller 310 transmita data signal to each of the source drivers 321-324 through transmissionlines (for example, conductive wires of a printed circuit board (PCB)),and the source drivers 321-324 drive the display panel 330 according tothe data signal to display an image. The implementation manners of thetiming controller 310 and the display panel 330 are not limited in thepresent embodiment. Based on a design requirement, for example, thetiming controller 310 may be a conventional timing controller or othercontrol circuits/elements, and the display panel may be a conventionaldisplay panel or other types of display panels. In some embodiments, thedata signal may not be limited to representing only data information andmay represent more control information such as timing controlinformation. In alternative or the same embodiments, the timingcontroller 310 can transmit one or more other signals to each of thesource drivers 321-324.

A receiving circuit disposed inside each of the source drivers 321-324may receive the data signal from the timing controller 310. Thereceiving circuit processes the data signal (i.e., an input signal)based on at least one operation parameter, so as to generate output datato other internal circuits (which are not shown). An anti-interferencecircuit disposed in each of the source drivers 321-324 may determinewhether an interference event occurs to the input signal based on theinput signal and/or the output data of the receiving circuit to obtain adetermination result. The “interference event” as referred to may bedefined as a RF noise occurring to the input signal and/or the energy ofthe RF noise being sufficiently large to interfere with the data signal(for example, the input signal of the receiving circuit). Based on adesign requirement, the “interference event” includes a common-modeinterference event, a high frequency interference event, a low frequencyinterference event and/or other interference events.

The anti-interference circuit may determine whether to adjust the atleast one operation parameter of the receiving circuit according to thedetermination result. For example, when no interference event occurs,the anti-interference circuit may maintain the at least one operationparameter of each receiving circuit at least one normal parameter. Whenan interference event occurs to the input signal of any one of thesource drivers 321-324, the anti-interference circuit maycorrespondingly adjust at least one corresponding operation parameter ofthe receiving circuit of the source driver whose input signal isinterfered, for example, adjust the at least one operation parameter ofthe receiving circuit of the source driver from the at least one normalparameter to at least one anti-interference parameter. After the atleast one operation parameter is adjusted to the at least oneanti-interference parameter, the anti-interference circuit may determinewhether to return the at least one operation parameter from the at leastone anti-interference parameter to the at least one normal parameterafter a predetermined time period. For example, in some embodiments,after the at least one operation parameter is adjusted to the at leastone anti-interference parameter, the anti-interference circuit may againdetermine whether the interference event occurs to the input signalsduring a blank period between a current frame and a next frame. In acondition that the interference event has disappeared, theanti-interference circuit may determine to return the at least oneoperation parameter from the at least one anti-interference parameter tothe at least one normal parameter. Alternatively, the anti-interferencecircuit may be configured to return the at least one operation parameterfrom the at least one anti-interference parameter to the at least onenormal parameter after a predetermined time period without determiningwhether the interference event occurs to the input signals.

The at least one operation parameter may be determined based on a designrequirement. For example, the at least one operation parameter mayinclude at least one operation parameter of a receiving amplifier ofeach receiving circuit, at least one operation parameter of a clock anddata recovery (CDR) circuits of each receiving circuit and/or otheroperation parameters. In some embodiments, the at least one operationparameter may include a high frequency gain, a low frequency gain, aratio of the high frequency gain to the low frequency gain, a biascurrent, a resistance value, a capacitance value and/or other operationparameters of the receiving amplifier. For example, when theinterference event occurs to the input signal of any one of the sourcedrivers 321-324, the anti-interference circuit may adjust the at leastone operation parameter of the receiving amplifier to increase a signalto noise ratio (SNR) of an output signals of the receiving amplifier. Insome other embodiments, the at least one operation parameter includes abandwidth of each CDR circuit. For example, when the interference eventincludes a high frequency interference component, the anti-interferencecircuit may decrease the bandwidth of the CDR circuit. For example, whenthe interference event includes a low frequency interference component,the anti-interference circuit may increase the bandwidth of the CDRcircuit.

FIG. 4 is a schematic circuit block diagram of an integrated circuit 400according to an embodiment of the invention. The integrated circuit 400is configured to drive the display panel 330. The source drivers 321-324illustrated in FIG. 3 may be inferred with reference to the descriptionrelated to the integrated circuit 400 illustrated in FIG. 4, and theintegrated circuit 400 illustrated in FIG. 4 may also refer to thedescription related to the source drivers 321-324 illustrated in FIG. 3.In the embodiment illustrated in FIG. 4, the integrated circuit 400includes a source driving circuit 410 and an anti-interference circuit420. The source driving circuit 410 is coupled to the timing controller310. A data signal provided by the timing controller 310 may serve as aninput signal 40 of the source driving circuit 410. Based on the inputsignal 40, the driving circuit 410 may drive the display panel 330 todisplay a corresponding image.

In the embodiment illustrated in FIG. 4, the source driver circuit 410includes a receiving circuit 411 and a driving circuit 412. Thereceiving circuit 411 may receive the input signal 40 including imagedata from another external integrated circuit (for example, the timingcontroller 310). Based on one or more operation parameters, thereceiving circuit 411 may process the input signal 40 to generate outputdata D2. The driving circuit 412 is coupled to the receiving circuit 411to receive the output data D2. Based on the output data D2, the drivingcircuit 412 may drive the display panel 330 to display a correspondingimage. The implementation manner of the driving circuit 412 is notlimited in the invention. Based on a design requirement, for example,the driving circuit 412 may include a shift register, a data register, alevel shifter, a digital-to-analog converter (DAC) and an output buffer.In some embodiments, the driving circuit 412 may be a conventional paneldriving circuit or other driving circuits/elements.

In the embodiment illustrated in FIG. 4, the source driver circuit 411includes a receiving amplifier 411 a and a CDR circuit 411 b. Based on adesign requirement, the receiving amplifier 411 a may include anequalizer, a differential amplifier and/or other amplificationcircuits/elements. The receiving amplifier 411 a may receive the inputsignal 40. The receiving amplifier 411 a may perform an equalizationoperation and/or a gain operation on the input signal 40 based on one ormore operation parameters to generate an input signal D1. The CDRcircuit 411 b is coupled to the receiving amplifier 411 a to receive theinput signal D1. The CDR circuit 411 b may recover image data and aclock from the input signal D1 based on the one or more operationparameters to generate the output data D2 and an output clock to thedriving circuit 412. Based on a design requirement, in some embodiments,the receiving amplifier 411 a may be a conventional amplifier, aconventional equalizer or other equalizer circuits/gain circuits, andthe CDR circuit 411 b may be a conventional CDR circuit or other CDRcircuits.

When the interference event does not yet occur to the input signal 40(for example, the RF noise 111 does not yet occur, or the energy of theRF noise 111 is insufficient to interfere with the input signal 40), theCDR circuit 411 b may correctly lock the data signal (i.e., the inputsignal 40) provided by the timing controller 310. When an interferingsource such as a mobile phone approaches the display apparatus 300, theRF noise Ill of the mobile phone may interfere with the transmission ofthe data signal (i.e., the input signal 40) between the timingcontroller 310 and the integrated circuit 400. When the energy of the RFnoise in the input signal 40 is sufficiently large, the CDR circuit 411b may probably be incapable of correctly locking the input signal 40.

FIG. 5 is a flowchart of an anti-interference method of an integratedcircuit according to an embodiment of the invention. Referring to FIG. 4and FIG. 5, in step S510, the receiving circuit 411 of the sourcedriving circuit 410 in the integrated circuit 400 may receive the inputsignal 40 including the image data from another external integratedcircuit (for example, the timing controller 310). The receiving circuit411, in step S510, may process the input signal 40 based on one or moreoperation parameters to generate the output data D2 to the drivingcircuit 412.

The anti-interference circuit 420 is coupled to the receiving circuit411. In step S520, the anti-interference circuit 420 may determinewhether an interference event occurs to the input signal 40 based on theinput signal 40 and/or the output data D2 to obtain a determinationresult. Based on a design requirement, the “interference event” asreferred to includes a common-mode interference event, a high frequencyinterference event, a low frequency interference event and/or otherinterference events. The anti-interference circuit 420, in step S520,may determine whether to adjust the at least one operation parameter ofthe receiving circuit 411 according to the determination result. Forexample, the anti-interference circuit 420 may detect a frequency of theinput signal 40, a common-mode level of the input signal 40, a swing ofthe input signal 40, an error code count of the output data D2 and/orother electric characteristics to obtain a detection result (i.e., thedetermination result). The anti-interference circuit 420 may determinewhether to adjust the at least one operation parameter of the receivingcircuit 411 according to the detection result.

For example, when the interference event does not occur, theanti-interference circuit 420 may maintain the at least one operationparameter of the receiving circuit 411 at least one normal parameter.When the interference event occurs to the input signal 40, theanti-interference circuit 420 may correspondingly adjust at least onecorresponding operation parameter of the receiving circuit 411, forexample, adjust the at least one operation parameter of the receivingcircuit 411 from the at least one normal parameter to at least oneanti-interference parameter. After the at least one normal parameteroperation parameter is adjusted to the at least one anti-interferenceparameter, the anti-interference circuit 420 may determine whether toreturn the at least one normal parameter operation parameter from the atleast one anti-interference parameter after a predetermined time period.For example, in some embodiments, after the at least one normalparameter operation parameter is adjusted to the at least oneanti-interference parameter, the anti-interference circuit 420 may againdetermine whether the interference event occurs to the input signal 40during a blank period of a next frame. In a condition that theinterference event has disappeared, the anti-interference circuit 420may determine to return the at least one normal parameter operationparameter from the at least one anti-interference parameter to the atleast one normal parameter.

The at least one operation parameter adjusted by the anti-interferencecircuit 420 may be determined based on a design requirement. Forexample, the at least one operation parameter may include at least oneoperation parameter of the receiving amplifier 411 a, at least oneoperation parameter of the CDR circuit 411 b and/or other operationparameters. In some embodiments, the at least one operation parametermay include a high frequency gain, a low frequency gain, a ratio of thehigh frequency gain to the low frequency gain, a bias current, aresistance value, a capacitance value and/or other operation parametersof the receiving amplifier 411 a. For example, when the interferenceevent occurs to the input signal 40, the anti-interference circuit 420may adjust the at least one operation parameter of the receivingamplifier 411 a to increase a signal to noise ratio (SNR) of the outputsignal (the input signal D1) of the receiving amplifier 411 a. In acondition that the receiving amplifier 411 a includes a conventionalequalizer, when the interference event occurs, the anti-interferencecircuit 420 may adjust a resistance value, a capacitance value and/or abias current of the equalizer to increase the SNR of the input signalD1.

In some other embodiments, the at least one operation parameter adjustedby the anti-interference circuit 420 may be include a bandwidth of theCDR circuit 411 b. For example, when the interference event includes ahigh frequency interference component, the anti-interference circuit 420may decrease the bandwidth of the CDR circuit 4111 b. When theinterference event includes a low frequency interference component, theanti-interference circuit 420 may increase the bandwidth of the CDRcircuit 411 b.

In the embodiment illustrated in FIG. 5, step S520 may include stepsS521 and S523. In other embodiments, step S520 may also include othersteps. In step S521, the anti-interference circuit 420 may determinewhether the interference event occurs to the input signal 40 based onthe input signal 40 and/or the output data D2. When the interferenceevent does not occur (i.e., the determination result of step S521 is“No”), the anti-interference circuit 420 may maintain the at least oneoperation parameter of the receiving circuit 411 at the at least onenormal parameter (step S523) and then, returns to step S510. When theinterference event occurs to an input signal 40 (i.e., the determinationresult of step S521 is “Yes”), the anti-interference circuit 420 mayadjust the at least one operation parameter of the receiving circuit 411from the at least one normal parameter to the at least oneanti-interference parameter (step S522) and then, returns to step S510.

After the at least one operation parameter of the receiving circuit 411is adjusted to the at least one anti-interference parameter, theanti-interference circuit 420 may again perform step S521 after apredetermined time period, so as to determine whether to return the atleast one operation parameter of the receiving circuit 411 from the atleast one anti-interference parameter to the at least one normalparameter. For example, in some embodiments, the anti-interferencecircuit 420 may again determine whether the interference event occurs tothe input signal 40 during a blank period of a next frame. In acondition that the interference event has disappeared (i.e., thedetermination result of step S521 is “No”), the anti-interferencecircuit 420 may determine to return the at least one operation parameterof the receiving circuit 411 from the at least one anti-interferenceparameter to the at least one normal parameter (step S523).

The at least one operation parameter may be determined/selected based ona design requirement. For example, the at least one operation parameterof the receiving circuit 411 may include one or more operationparameters of the receiving amplifier 411 a (i.e., the equalizer), oneor more operation parameters of the CDR circuit 411 b and/or otheroperation parameters. In some embodiments, the one or more operationparameter of the receiving circuit 411 may include a high frequencygain, a low frequency gain, a ratio of the high frequency gain to thelow frequency gain, a bias current, a resistance value, a capacitancevalue and/or other operation parameters of the receiving amplifier 411a. When the interference event occurs to an input signal 40, theanti-interference circuit 420 may adjust the at least one operationparameter of the receiving amplifier 411 a to increase the SNR of theoutput signal (the input signal D1) of the receiving amplifier 411 a. Insome other embodiments, the at least one operation parameter of thereceiving circuit 411 may also include the bandwidth of the CDR circuit411 b. When the interference event includes a high frequencyinterference component, the anti-interference circuit 420 may decreasethe bandwidth of the CDR circuit 411 b. When the interference eventincludes a low frequency interference component, the anti-interferencecircuit 420 may increase the bandwidth of the CDR circuit 411 b.

FIG. 6 is a schematic circuit block diagram of the anti-interferencecircuit 420 depicted in FIG. 4 according to an embodiment of theinvention. In the embodiment illustrated in FIG. 6, the timingcontroller 420 includes an interference detector circuit 421 and acontrol circuit 422. The interference detector circuit 421 may detectthe input signal 40 or the output data D2 to obtain a detection result.The detection result may indicate whether the interference event occurs.The control circuit 422 is coupled to the interference detector circuit421 to receive the detection result. The control circuit 422 maydetermine whether to adjust the at least one operation parameter of thereceiving circuit 411 according to the detection result.

The occurrence of the interference event includes the occurrence of oneor more of a common-mode error event, a swing error event, a highfrequency event and an error code event. Based on a design requirement,the interference detector circuit 421 may include one of the following,a common-mode level detection circuit, a swing detection circuit, a highfrequency detection circuit, an error detection circuit and/or otherdetection circuits. The common-mode level detection circuit may detectwhether a common-mode error event with respect to the input signal 40occurs. The swing detection circuit may detect whether a swing errorevent with respect to the input signal 40 occurs. The high frequencydetection circuit may detect whether a high frequency event with respectto the input signal 40 occurs. The error detection circuit may detectwhether an error code event with respect to the output data D2 occurs.Several embodiments are provided below to describe implementationdetails related to the common-mode level detection circuit, the swingdetection circuit, the high frequency detection circuit and the errordetection circuit. The control circuit 422 may count an occurrencenumber of one or more of the common-mode error event, the swing errorevent and the error code event and determine whether to adjust the atleast one operation parameter of the receiving circuit 411 according tothe occurrence number.

The common-mode level detection circuit in the interference detectorcircuit 421 may detect the common-mode level of the input signal 40, soas to determine whether the common-mode error event (i.e., theinterference event) with respect to the common-mode level of the inputsignal 40 occurs. When the common-mode level detection circuit (i.e.,the interference detector circuit 421) notifies the control circuit 422that the common-mode error event occurs to the input signal 40 (i.e.,the interference event occurs), the control circuit 422 may determinewhether to adjust the at least one operation parameter of the receivingcircuit 411 according to the notification of the common-mode leveldetection circuit.

FIG. 7 is a schematic circuit block diagram of a common-mode leveldetection circuit in the interference detector circuit 421 according toan embodiment of the invention. The interference detector circuit 421and the control circuit 422 illustrated in FIG. 7 may refer to thedescription related to FIG. 6 and thus, will not be repeated. In theembodiment illustrated in FIG. 7, the common-mode level detectioncircuit of the interference detector circuit 421 includes a common-modevoltage detection circuit 710, a reference voltage generating circuit720, a first comparator CMP1, a second comparator CMP2 and an AND gateAND1. The common-mode voltage detection circuit 710 may detect acommon-mode level VCM of the input signal 40. The reference voltagegenerating circuit 720 is coupled to the common-mode voltage detectioncircuit 710 to receive the common-mode level VCM. The reference voltagegenerating circuit 720 may generate a first reference level VH and asecond reference level VL based on the common-mode level VCM. Thereference voltage generating circuit 720 may provide the first referencelevel VH and the second reference level VL to the first comparator CMP1and the second comparator CMP2.

In the embodiment illustrated in FIG. 7, the common-mode voltagedetection circuit 710 includes resistors R1 and R2. The input signal 40may be a differential signal. A first terminal of the resistor R1receives the first terminal signal 40P of the input signal 40, and afirst terminal of the resistor R2 receives the second terminal signal40N of the input signal 40. A second terminal of the resistor R1 and asecond terminal of the resistor R2 are commonly coupled to a common-modenode Ni providing the common-mode level VCM to the first comparator CMP1and the second comparator CMP2.

The reference voltage generating circuit 720, for example, includes anoperational amplifier OP1, resistors R3, R4, R5 and R6 and a capacitorC1. A first input terminal (for example, a non-inverting input terminal)of the operational amplifier OP1 is coupled to the common-mode voltagedetection circuit 710 to receive the common-mode level VCM. A firstterminal of the resistor R3 is coupled to an output terminal of theoperation amplifier OP1. A second terminal of the resistor R3 mayprovide the first reference level VH to the first comparator CMP1. Afirst terminal of the resistor R4 is coupled to the second terminal ofthe resistor R3. A second terminal of the resistor R4 is coupled to asecond input terminal (for example, an inverting input terminal) of theoperation amplifier OP1. A first terminal of the resistor R5 is coupledto the second terminal of the resistor R4. A second terminal of theresistor R5 may provide the second reference level VL to the secondcomparator CMP2. A first terminal of the resistor R6 is coupled to thesecond terminal of the resistor R5. A second terminal of the resistor R6is coupled to a reference voltage (for example, a ground voltage GND orany other fixed voltage). A first terminal of the capacitor C1 iscoupled to the second input terminal of the operation amplifier OP1. Asecond terminal of the capacitor C1 is coupled to the reference voltage(for example, the ground voltage GND or any other fixed voltage).

In the embodiment illustrated in FIG. 7, a first input terminal (forexample, a non-inverting input terminal) of the first comparator CMP1 iscoupled to the common-mode voltage detection circuit 710 to receive thecommon-mode level VCM. A second input terminal (for example, aninverting input terminal) of the first comparator CMP1 is coupled to thecommon-mode voltage detection circuit 710 to receive the first referencelevel VH. The first comparator CMP1 may compare the common-mode levelVCM with the first reference level VH to output a first comparisonresult to the AND gate AND1. A first input terminal (for example, anon-inverting input terminal) of the second comparator CMP2 is coupledto the common-mode voltage detection circuit 710 to receive the secondreference level VL. A second input terminal (for example, an invertinginput terminal) of the second comparator CMP2 is coupled to thecommon-mode voltage detection circuit 710 to receive the common-modelevel VCM. The second comparator CMP2 may compare the common-mode levelVCM with the second reference level VL to output a second comparisonresult to the AND gate AND1. A first input terminal of the AND gate AND1is coupled to the first comparator CMP1 to receive the first comparisonresult. A second input terminal of the AND gate AND1 is coupled to thesecond comparator CMP2 to receive the second comparison result. Anoutput terminal of the AND gate AND1 is coupled to the control circuit422 to provide the detection result to the control circuit 422.

When the RF noise 111 does not occur yet, or the energy of the RF noise111 is insufficient to interfere with the input signal 40, thecommon-mode level VCM falls within a range between the first referencelevel VH and the second reference level VL. When the common-mode levelVCM falls within the range between the first reference level VH and thesecond reference level VL, the output of the AND gate AND1 is at a lowlogic level. When the energy of the RF noise in the input signal 40 issufficiently large, the common-mode level VCM may probably be greaterthan the first reference level VH, or the common-mode level VCM mayprobably be smaller than the second reference level VL. When thecommon-mode level VCM is greater than the first reference level VH, orthe common-mode level VCM is smaller than the second reference level VL,the output of the AND gate AND1 is at a high logic level, therebyindicating that the common-mode error event (i.e., the interferenceevent) has occurred to the input signal 40.

It should be noted that the implementation manner of the common-modelevel detection circuit in the interference detector circuit 421 shouldnot be limited to the disclosure illustrated in FIG. 7. For example, inother embodiments, the first reference level VH and/or the secondreference level VL may be configured as fixed voltage levels. The firstreference level VH and/or the second reference level VL may be anyvoltage levels determined based on a design requirement. For example, inan embodiment, the first reference level VH and the second referencelevel VL may respectively be an upper limit level and a lower limitlevel of a rated range of the common-mode level VCM in a normaloperation state. When the RF noise 111 does not occur yet, or the energyof the RF noise 111 is insufficient to interfere with the input signal40, the common-mode level VCM falls within the rated range.

FIG. 8 is a schematic circuit block diagram of the common-mode leveldetection circuit in the interference detector circuit 421 according toanother embodiment of the invention. The interference detector circuit421 and the control circuit 422 illustrated in FIG. 8 may refer to thedescription related to FIG. 6 and thus, will not be repeated. In theembodiment illustrated in FIG. 8, the common-mode level detectioncircuit of the interference detector circuit 421 includes a common-modevoltage detection circuit 710 and a comparator CMP3. The sensing circuit710 illustrated in FIG. 8 may refer to the description related to FIG. 7and thus, will not be repeatedly described.

A first input terminal of the comparator CMP3 is coupled to thecommon-mode voltage detection circuit 710 to receive the common-modelevel VCM. A second input terminal of the comparator CMP3 receives areference voltage VREF. The reference level VREF may be any voltagelevel determined based on a design requirement. The comparator CMP3 maycompare the common-mode level VCM with the reference level VREF toobtain a comparing result. An output terminal of the comparator CMP3 iscoupled to the control circuit 422 to provide the detection resultaccording to the comparison result.

For example, in an embodiment, the reference level VREF may be an upperlimit level of a rated range of the common-mode level VCM in a normaloperation state. When the RF noise 111 does not occur yet, or the energyof the RF noise 111 is insufficient to interfere with the input signal40, the common-mode level VCM falls within the rated range. When thecommon-mode level VCM is smaller than the reference level VREF, theoutput of the comparator CMP3 is at a low logic level. When the energyof the RF noise in the input signal 40 is sufficiently large, thecommon-mode level VCM may probably be greater than the reference levelVREF. When the common-mode level VCM is greater than the reference levelVREF, the output of the comparator CMP3 is at a high logic level,thereby indicating that the common-mode error event (i.e., theinterference event) has occurred to the input signal 40.

In another embodiment, the reference level VREF may be a lower limitlevel of the rated range of the common-mode level VCM in a normaloperation state. When the RF noise 111 does not occur yet, or the energyof the RF noise 111 is insufficient to interfere with the input signal40, the common-mode level VCM falls within the rated range. When thecommon-mode level VCM is greater than the reference level VREF, theoutput of the comparator CMP3 is at a low logic level. When the energyof the RF noise in the input signal 40 is sufficiently large, thecommon-mode level VCM may probably be smaller than the reference levelVREF. When the common-mode level VCM is smaller than the reference levelVREF, the output of the comparator CMP3 is at a high logic level,thereby indicating that the common-mode error event (i.e., theinterference event) has occurred to the input signal 40.

The swing detection circuit in the interference detector circuit 421 maydetect a swing of the input signal 40, so as to determine whether theswing error event (i.e., the interference event) with respect to theswing of the input signal 40 occurs. When the swing detection circuit(i.e., the interference detector circuit 421) notifies the controlcircuit 422 that the swing error event occurs to the input signal 40(i.e., the interference event occurs), the control circuit 422 maydetermine whether to adjust the at least one operation parameter of thereceiving circuit 411 according to the notification of the swingdetection circuit.

FIG. 9 is a schematic circuit block diagram of the swing detectioncircuit in the interference detector circuit 421 according to anembodiment of the invention. The interference detector circuit 421 andthe control circuit 422 illustrated in FIG. 9 may refer to thedescription related to FIG. 6 and thus, will not be repeated. In theembodiment illustrated in FIG. 9, the swing detection circuit in theinterference detector circuit 421 includes a comparator CMP4. A firstdifferential input terminal pair of the comparator CMP4 may receive thefirst terminal signal 40P and the second terminal signal 40N in theinput signal 40. A second differential input terminal pair of thecomparator CMP4 may receive the first reference level VH and the secondreference level VL. An output terminal of the comparator CMP4 is coupledto the control circuit 422 to provide the detection result.

The comparator CMP4 may compare whether the swing of the input signal 40exceeds a rated range defined by the first reference level VH and thesecond reference level VL. When the RF noise 111 does not occur yet, orthe energy of the RF noise 111 is insufficient to interfere with theinput signal 40, the swing of the input signal 40 falls within the ratedrange. When the swing of the input signal 40 falls within the ratedrange, the output of the comparator CMP4 is at a low logic level. Whenthe energy of the RF noise in the input signal 40 is sufficiently large,the swing of the input signal 40 may probably exceed the rated range.When the swing of the input signal 40 exceeds the rated range, theoutput of the comparator CMP4 is at a high logic level, therebyindicating that the swing error event (i.e., the interference event) hasoccurred to the input signal 40.

It should be noted that in some embodiments, a method of generating thefirst reference level VH and the second reference level VL illustratedin FIG. 9 may be inferred with reference to the description related tothe reference voltage generating circuit 720 illustrated in FIG. 7 andthus, will not be repeated. Namely, the first reference level VH and/orthe second reference level VL may be dynamic voltage levels in responseto the common-mode level VCM of the input signal 40. In otherembodiments, the first reference level VH and/or the second referencelevel VL may be configured as any fixed voltage levels. The voltagelevels of the first reference level VH and/or the second reference levelVL may be determined based on a design requirement in a scenario wherethey are configured as fixed voltages. For example, the first referencelevel VH and the second reference level VL may respectively be an upperlimit level and a lower limit level of a rated swing range of the inputsignal 40 in a normal operation state. When the RF noise 111 does notoccur yet, or the energy of the RF noise 111 is insufficient tointerfere with the input signal 40, the swing of the input signal 40falls within the rated swing range.

The high frequency detection circuit in the interference detectorcircuit 421 may detect the frequency of the input signal 40. Generally,a frequency of the RF noise is higher than the frequency of the inputsignal 40. Thus, when the high frequency detection circuit detects thatthe high frequency event occurs to the input signal 40, the highfrequency detection circuit may determine that the interference eventoccurs to the input signal 40. When the high frequency detection circuitin the interference detector circuit 421 notifies the control circuit422 that the high frequency event (i.e., the interference event) occursto the input signal 40, the control circuit 422 may determine whether toadjust the at least one operation parameter of the receiving circuit 411according to the notification of the high frequency detection circuit.

FIG. 10 is a schematic circuit block diagram of the high frequencydetection circuit in the interference detector circuit 421 according toanother embodiment of the invention. The interference detector circuit421 and the control circuit 422 illustrated in FIG. 10 may refer to thedescription related to FIG. 6 and thus, will not be repeated. In theembodiment illustrated in FIG. 10, the high frequency detection circuitof the interference detector circuit 421 includes a switch SW1,resistors R7 and R8 and a capacitor C2. A first terminal of the switchSW1 is coupled to a first voltage (for example, a system voltage VDD). Acontrol terminal of the switch SW1 receives the input signal 40. In acondition that the input signal 40 is a differential signal, the controlterminal of the switch SW1 may receive the first terminal signal 40P orthe second terminal signal 40N of the input signal 40.

A first terminal of the resistor R7 is coupled to a second terminal ofthe switch SW1. A second terminal of the resistor R7 is coupled to asecond voltage (for example, a ground voltage GND). A first terminal ofthe resistor R8 is coupled to the second terminal of the switch SW1. Asecond terminal of the resistor R8 is coupled to the control circuit 422to provide the detection result. A first terminal of the capacitor C2 iscoupled to the second terminal of the resistor R8. A second terminal ofthe capacitor C2 is coupled to a third voltage (for example, a groundvoltage GND). A turn-on frequency of the switch SW1 is in response tothe frequency of the input signal 40. When the switch SW1 is turned on,the system voltage VDD may charge the capacitor C2 via the resistor R8.On the other hand, the charge stored in the capacitor C2 may be released(discharged) via the resistors R8 and R7. When a speed of the chargingis greater than a speed of the discharging, a voltage (i.e., thedetection result) of the capacitor C2 is pulled up. In other words, whenthe high frequency event occurs to the input signal 40, the voltage ofthe capacitor C2 is pulled up. The control circuit 422 may acquirewhether the high frequency event (i.e., the interference event) occursto the input signal 40 according to the voltage of the capacitor C2.Thus, the high frequency detection circuit in the interference detectorcircuit 421 may detect the frequency of the input signal 40, so as todetermine whether the high frequency event (i.e., the interferenceevent) occurs to the input signal 40.

The error detection circuit in the interference detector circuit 421 maydetect a bit error rate (or an error code count) of the output data D2,so as to determine whether the error code event (i.e., the interferenceevent) occurs to the output data D2. For example, according to aspecific transmission protocol (i.e., a specific transmission format), aspecific bit (or some specific bits) of a specific position in theoutput data D2 certainly has a specific specified pattern (for example,“01”). If the specified pattern does not appear to the specificposition, the error detection circuit may acquire that errors occur tothe output data D2. By calculating a count (i.e., the error code count)of the errors occurring to the output data D2 or a frequency (i.e., thebit error rate) of the errors occurring to the output data D2, the errordetection circuit may determine whether the error code event occurs tothe output data D2. When the error detection circuit (i.e., theinterference detector circuit 421) notifies the control circuit 422 thatthe error code event (i.e., the interference event) occurs to the outputdata D2, the control circuit 422 may determine whether to adjust the atleast one operation parameter of the receiving circuit 411 according tothe notification of the error detection circuit.

FIG. 11 is a schematic circuit block diagram of the error detectioncircuit in the interference detector circuit 421 according to anembodiment of the invention. The interference detector circuit 421 andthe control circuit 422 illustrated in FIG. 11 may refer to thedescription related to FIG. 6 and thus, will not be repeated. In theembodiment illustrated in FIG. 11, the error detection circuit of theinterference detector circuit 421 includes an error code comparator 1110and an accumulator 1120. The error code comparator 1110 is coupled tothe receiving circuit 411 to receive the output data D2. The error codecomparator 1110 may compare the output data D2 with a specifictransmission format to obtain an identification result indicatingwhether the output data D2 meets the transmission format. Thetransmission format may be determined based on a design requirement andis not limited in the present embodiment.

For example, according to a specific transmission protocol (i.e., atransmission format), a specific bit (or some specific bits) of aspecific position in the output data D2 certainly has a specificspecified pattern (for example, “01”). If the specified pattern does notappear to the specific position, the error code comparator 1110 mayacquire that errors occur to the output data D2. Thus, the error codecomparator 1110 may output a logic value of “1” (i.e., an identificationresult) to the accumulator 1120. If the output data D2 meets thetransmission format, the error code comparator 1110 may output a logicvalue of “0” (i.e., an identification result) to the accumulator 1120.

An input terminal of the accumulator 1120 is coupled to an outputterminal of the error code comparator 1110 to receive the identificationresults. The accumulator 1120 accumulates the identification results toobtain an accumulation result. When the output of the error codecomparator 1110 is 1, the accumulation result of the accumulator 1120 isadded by 1. When the accumulation result exceeds a specificpredetermined number, the accumulation result indicates whether theerror code event (i.e., the interference event) occurs. Thepredetermined number may be determined based on a design requirement andis not limited in the present embodiment. Thus, the error detectioncircuit in the interference detector circuit 421 may detect whethererrors occur to the output data D2, so as to determine whether the errorcode event (i.e., the interference event) occurs to the output data D2.

FIG. 12 is a schematic circuit block diagram of the CDR circuit 411 bdepicted in FIG. 4 according to an embodiment of the invention. In theembodiment illustrated in FIG. 12, the CDR circuit 411 b includes phasedetector (PD) 1210, a charge pump (CP) 1220, a low pass filter (LPF)1230 and a voltage controlled oscillator (VCO) 1240. The PD 1210receives the input signal D1 from the receiving amplifier 411 a andreceives an output clock CLK from the VCO 1240. According to a phase ofthe output clock CLK, the PD 1210 may sample a data component from theinput signal D1 to generate the output data D2 to the driving circuit412. In addition, the PD 1210 may compare/detect a phase relationbetween a clock component and the output clock CLK of the input signalD1 and then, provide the detection result to the CP 1220.

An input terminal of the CP 1220 is coupled to an output terminal of thePD 1210. An input terminal of the LPF 1230 is coupled to an outputterminal of the CP 1220. An input terminal of the VCO 1240 is coupled toan output terminal of the LPF 1230. The PD 1210, the CP 1220, the LPF1230 and the VCO 1240 are not limited in the present embodiment. Forexample, the PD 1210 may be a conventional phase detector or other phasedetectors, the CP 1220 may be a conventional charge pump or other chargepumps, the LPF 1230 may be a conventional low pass filter or other lowpass filters, and the VCO 1240 may be a conventional voltage controlledoscillator or other voltage controlled oscillators. The output clock CLKgenerated by the VCO 1240 may be provided to the driving circuit 412.

When the interference event occurs to the input signal 40, theanti-interference circuit 420 may selectively adjust the at least oneoperation parameter of the CDR circuit 411 b. Based on a designrequirement, the at least one operation parameter of the CDR circuit 411b includes at least one of a CP current of the CP 1220 and an LPFresistance of the LPF 1230. For example, when the interference eventoccurs to the input signal 40, the anti-interference circuit 420 mayselectively decrease the CP current of the CP 1220 and/or selectivelydecrease the LPF resistance of the LPF 1230, thereby adjusting thebandwidth of the CDR circuit 411 b.

Based on different design demands, blocks of the anti-interferencecircuit 420 and/or the control circuit 422 may be implemented in a formof hardware, firmware, software (i.e., programs) or in a combination ofmany of the aforementioned three forms.

In terms of the hardware form, the blocks of the anti-interferencecircuit 420 and/or the control circuit 422 may be implemented in a logiccircuit on the integrated circuit. Related functions of theanti-interference circuit 420 and/or the control circuit 422 may beimplemented in a form of hardware by utilizing hardware descriptionlanguages (e.g., Verilog HDL or VHDL) or other suitable programminglanguages. For example, the related functions of the anti-interferencecircuit 420 and/or the control circuit 422 may be implemented in one ormore controllers, micro-controllers, microprocessors,application-specific integrated circuits (ASICs), digital signalprocessors (DSPs), field programmable gate arrays (FPGAs) and/or variouslogic blocks, modules and circuits in other processing units.

In terms of the software form and/or the firmware form, the relatedfunctions of the anti-interference circuit 420 and/or the controlcircuit 422 may be implemented as programming codes. For example, theanti-interference circuit 420 and/or the control circuit 422 may beimplemented by using general programming languages (e.g., C or C++) orother suitable programming languages. The programming codes may berecorded/stored in recording media. The aforementioned recording mediainclude a read only memory (ROM), a storage device and/or a randomaccess memory (RAM). Additionally, the programming codes may be accessedfrom the recording medium and executed by a computer, a centralprocessing unit (CPU), a controller, a micro-controller or amicroprocessor to accomplish the related functions. As for the recordingmedium, a non-transitory computer readable medium, such as a tape, adisk, a card, a semiconductor memory or a programming logic circuit, maybe used. In addition, the programs may be provided to the computer (orthe CPU) through any transmission medium (e.g., a communication networkor radio waves). The communication network is, for example, theInternet, wired communication, wireless communication or othercommunication media.

Based on the above, the receiving circuit of the integrated circuitprovided by the embodiments of the invention can process the inputsignal based on the at least one operation parameter, so as to generatethe output data to other internal circuits (for example, the drivingcircuit). The anti-interference circuit of the integrated circuit candetermine whether any interference event occurs to the input signal, soas to determine whether to adjust the at least one operation parameterof the receiving circuit according to the determination result. The atleast one operation parameter may include one or more of the highfrequency gain, the low frequency gain, the ratio of the high frequencygain to the low frequency gain, the bias current, the resistance value,the capacitance value and other operation parameters of the receivingcircuit. When detecting the occurrence of the interference event, theanti-interference circuit can dynamically adjust the at least oneoperation parameter of the receiving circuit, so as to automaticallyresist the interference. After the noise disappears, theanti-interference circuit can automatically return the at least oneoperation parameter of the receiving circuit back to the at least onenormal parameter. In this way, when the noise comes (i.e., theinterference event occurs), the anti-interference circuit canautomatically change the related operation parameters. After the noisedisappears, the anti-interference circuit can automatically return theat least one operation parameter back to the normal parameter to preventunnecessary current consumption.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the structure of thedisclosed embodiments without departing from the scope or spirit of thedisclosure. In view of the foregoing, it is intended that the disclosurecover modifications and variations of this disclosure provided they fallwithin the scope of the following claims and their equivalents.

What is claimed is:
 1. An integrated circuit, configured to drive adisplay panel, comprising: a source driving circuit, configured toreceive an input signal comprising image data and process the inputsignal based on at least one operation parameter to generate outputdata; and an anti-interference circuit, coupled to the source drivingcircuit, and configured to adjust the at least one operation parameterof the source driving circuit according to whether an interference eventoccurs to the input signal.
 2. The integrated circuit according to claim1, wherein the anti-interference circuit is configured to determinewhether the interference event occurs to the input signal based on theinput signal or the output data and adjust the at least one operationparameter of the source driving circuit according to a result of thedetermination.
 3. The integrated circuit according to claim 2, whereinthe anti-interference circuit is configured to detect at least one of afrequency of the input signal and determine whether to adjust the atleast one operation parameter of the source driving circuit according toa result of the detection.
 4. The integrated circuit according to claim2, wherein the anti-interference circuit is configured to detect acommon-mode level of the input signal to obtain a result of thedetection and determine whether to adjust the at least one operationparameter of the source driving circuit according to the result of thedetection.
 5. The integrated circuit according to claim 2, wherein theanti-interference circuit is configured to detect a swing of the inputsignal to obtain a result of the detection and determine whether toadjust the at least one operation parameter of the source drivingcircuit according to the result of the detection.
 6. The integratedcircuit according to claim 2, wherein the anti-interference circuit isconfigured to detect an error code count of the output data to obtain aresult of the detection and determine whether to adjust the at least oneoperation parameter of the source driving circuit according to theresult of the detection.
 7. The integrated circuit according to claim 2,wherein the anti-interference circuit comprises: an interferencedetector circuit, configured to detect the input signal or the outputdata to obtain a result of the detection indicating whether theinterference event occurs; and a control circuit, coupled to theinterference detector circuit to receive the result of the detection andconfigure to determine whether to adjust the at least one operationparameter of the source driving circuit according to the result of thedetection.
 8. The integrated circuit according to claim 7, wherein theinterference detector circuit comprises a common-mode level detectioncircuit, configured to detect whether a common-mode error event withrespect to a common-mode level of the input signal occurs, wherein theoccurrence of the interference event comprises occurrence of thecommon-mode error event.
 9. The integrated circuit according to claim 7,wherein the interference detector circuit comprises a swing detectioncircuit, configured to detect whether a swing error event with respectto a swing of the input signal occurs, wherein the occurrence of theinterference event comprises occurrence of the swing error event. 10.The integrated circuit according to claim 7, wherein the interferencedetector circuit comprises a high frequency detection circuit,configured to detect whether a high frequency event with respect to theinput signal occurs, wherein the occurrence of the interference eventcomprises occurrence of the high frequency event.
 11. The integratedcircuit according to claim 7, wherein the interference detector circuitcomprises an error detection circuit, configured to detect whether anerror code event with respect to the output data occurs, wherein theoccurrence of the interference event comprises occurrence of the errorcode event.
 12. The integrated circuit according to claim 7, wherein thecontrol circuit is configured to count an occurrence number for theinterference event and determine whether to adjust the at least oneoperation parameter of the source driving circuit according to theoccurrence number.
 13. The integrated circuit according to claim 8,wherein the common-mode level detection circuit comprises: a common-modevoltage detection circuit, configured to detect the common-mode level ofthe input signal.
 14. The integrated circuit according to claim 13,wherein the common-mode level detection circuit further comprises: afirst comparator, coupled to the common-mode voltage detection circuitto receive the common-mode level and comparing the common-mode levelwith a first reference level to output a first comparison result; asecond comparator, coupled to the common-mode voltage detection circuitto receive the common-mode level and comparing the common-mode levelwith a second reference level to output a second comparison result; andan AND gate, having a first input terminal coupled to the firstcomparator to receive the first comparison result, a second inputterminal coupled to the second comparator to receive the secondcomparison result and an output terminal coupled to the control circuitto provide the result of the detection.
 15. The integrated circuitaccording to claim 13, wherein the common-mode level detection circuitfurther comprises: a comparator, having an input terminal coupled to thecommon-mode voltage detection circuit to receive the common-mode level,comparing the common-mode level with a reference level to obtain acomparison result and having an output terminal coupled to the controlcircuit to provide the result of the detection according to thecomparison result.
 16. The integrated circuit according to claim 14,wherein the common-mode level detection circuit comprises: a firstresistor, having a first terminal configured to receive a first terminalsignal in the input signal and a second terminal coupled to acommon-mode node, wherein the common-mode node provides the common-modelevel to the first comparator and the second comparator; and a secondresistor, having a first terminal configured to receive a secondterminal signal in the input signal and a second terminal coupled to thecommon-mode node.
 17. The integrated circuit according to claim 14,wherein the interference detector circuit further comprises: a referencevoltage generating circuit, coupled to the common-mode voltage detectioncircuit to receive the common-mode level and generating the firstreference level and the second reference level based on the common-modelevel.
 18. The integrated circuit according to claim 17, wherein thereference voltage generating circuit comprises: an operationalamplifier, having a first input terminal coupled to the common-modevoltage detection circuit to receive the common-mode level; a firstresistor, having a first terminal coupled to an output terminal of theoperational amplifier and a second terminal providing the firstreference level to the first comparator; a second resistor, having afirst terminal coupled to the second terminal of the first resistor anda second terminal coupled to a second input terminal of the operationalamplifier; a third resistor, having a first terminal coupled to thesecond terminal of the second resistor and a second terminal providingthe second reference level to the second comparator; and a fourthresistor, having a first terminal coupled to the second terminal of thethird resistor and a second terminal coupled to a reference voltage. 19.The integrated circuit according to claim 9, wherein the swing detectioncircuit comprises: a comparator, having a first differential inputterminal pair and a second differential input terminal pair, wherein thefirst differential input terminal pair is configured to receive a firstterminal signal and a second terminal signal in the input signal, thesecond differential input terminal pair is configured to receive a firstreference level and a second reference level, and an output terminal ofthe comparator is coupled to the control circuit to provide the resultof the detection.
 20. The integrated circuit according to claim 10,wherein the high frequency detection circuit comprises: a switch, havinga first terminal coupled to a first voltage and a control terminalreceiving the input signal; and a RC circuit, comprising a plurality ofresistors and at least one capacitor coupled to the resistors, whereinthe RC circuit is coupled to a second terminal of the switch and coupledto the control circuit to provide the result of the detection to thecontrol circuit.
 21. The integrated circuit according to claim 11,wherein the error detection circuit comprises: an error code comparator,configured to receive the output data and configured to compare theoutput data and a transmission format to obtain an identification resultindicating whether the output data meets the transmission format; and anaccumulator, having an input terminal coupled to the error codecomparator to receive the identification result and accumulating theidentification result to obtain an accumulation result indicating thatthe error code event occurs when the accumulation result exceeds apredetermined number.
 22. The integrated circuit according to claim 1,wherein the source driving circuit further comprises a receivingcircuit, the receiving circuit comprising: a receiving amplifier,configured to receive the input signal; and a clock and data recoverycircuit, configured to recover the image data and a clock from the inputsignal based on the at least one operation parameter to generate theoutput data and an output clock.
 23. An anti-interference method,applicable for an integrated circuit configured to drive a displaypanel, the anti-interference method comprising: receiving an inputsignal comprising image data and process the input signal based on atleast one operation parameter to generate output data, by a sourcedriving circuit; and adjusting the at least one operation parameter ofthe source driving circuit according to whether an interference eventoccurs to the input signal.
 24. The anti-interference method accordingto claim 23, further comprising determining whether the interferenceevent occurs to the input signal based on the input signal or the outputdata and wherein the adjusting the at least one operation parameter ofthe source driving circuit is performed according to a result of thedetermination.
 25. The anti-interference method according to claim 23,further comprising detecting, by the source driving circuit, whether acommon-mode error event with respect to a common-mode level of the inputsignal occurs, wherein the occurrence of the interference eventcomprises occurrence of the common-mode error event.
 26. Theanti-interference method according to claim 23, further comprisingdetecting, by the source driving circuit, whether a swing error eventwith respect to a swing of the input signal occurs, wherein theoccurrence of the interference event comprises occurrence of the swingerror event.
 27. The anti-interference method according to claim 23,further comprising detecting, by the source driving circuit, whether ahigh frequency event with respect to the input signal occurs, whereinthe occurrence of the interference event comprises occurrence of thehigh frequency event.
 28. The anti-interference method according toclaim 23, further comprising detecting, by the source driving circuit,whether an error code event with respect to the output data occurs,wherein the occurrence of the interference event comprises occurrence ofthe error code event
 29. The anti-interference method according to claim23, further comprising: receiving and amplifying the input signal; andrecovering the image data and a clock from the input signal based on theat least one operation parameter to generate the output data and anoutput clock.